JP2013086127A - Apparatus and method for removing liquid on surface of plate - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus for removing liquid on the surface of a plate, which generates little noise, uses little energy wastefully, has low possibility of re-contamination of a steel plate surface, useable for a wide steel plate and is durable to long-term continuous use, and to provide a method for removing the liquid on the surface of the steel plate.SOLUTION: The apparatus 1 for removing liquid on the surface of the steel plate is adopted, which includes: a drain roll 3 which includes in the surface 3a thereof, a porous elastic body layer 2 that can absorb the liquid 12 stuck to the surface 11a of the plate; and a squeeze roll 4 which is pressed against the drain roll 3 so as to crush the porous elastic body layer 2. The apparatus 1 for removing the liquid on the surface of the steel plate is constituted in such away that the liquid 12 which is squeezed from the porous elastic body layer 2 by means of the squeeze roll 4 is discharged along the direction of the rotating shafts of the squeeze roll 4 and the drain roll 3.

Description

  The present invention relates to a plate surface liquid removing device and a plate surface liquid removing method, and more particularly, a method for removing liquid such as water and chemicals attached to the surface of a steel plate, specifically, a thin plate, a thick plate, a plated steel plate, and the like. And an apparatus.

  In the field of industrial production, a liquid such as water or various chemicals is applied or sprayed on a workpiece for the purpose of various chemical treatments, cleaning or cooling, and then the liquid adhering to the surface is wiped off and then the workpiece is subjected to the next process. Often used for processing. At this time, it is necessary to remove the liquid such as water or various chemicals used in the previous step.

  Generally, air, nitrogen, or the same type of liquid as the liquid you want to remove is sprayed on the work surface, a rubber roll is pressed from both sides of the work to squeeze the liquid, or the work surface liquid is Various methods such as a method of absorbing in a sponge roll are known.

  More specifically, Patent Document 1 below discloses a liquid draining device that removes coolant liquid adhering to the surface of a steel sheet by air purge that is jetted from an air nozzle. Further, in the following Patent Document 2, in a device that sandwiches a sheet-like material between a pair of rolls and removes moisture adhering to the surface, one or both of the rolls are draining rolls having a sponge portion. A moisture removing device is disclosed in which a moisture suction nozzle is pressure-bonded to the sponge portion.

Japanese Utility Model Publication No. 5-65411 Utility Model Registration No. 3002532

  However, in the method described in Patent Document 1, it is necessary to continuously inject a large amount of high-pressure gas such as air or nitrogen onto the surface of the steel plate, resulting in a large noise caused by the injection of high-pressure gas and generating high-pressure gas. There is a problem that a large amount of energy is wasted. Further, there is a risk that the steel plate is contaminated again by the splash scattered from the surface of the steel plate by the injection of the high-pressure gas.

  Also, the method of squeezing the liquid by pressing rubber rolls from both sides of the work surface, when the work surface is low in flatness and the work surface has waviness, the roll is stretched over the entire width of the work piece. There was a problem that it was difficult to apply the pressure uniformly, and a defect in which the liquid remained partially occurred. In addition, there is a problem that it is difficult to apply to a wide workpiece because a contact failure with the workpiece due to bending of the roll itself is likely to occur.

  Furthermore, in the method of absorbing the liquid by the sponge roll, there is a problem in discharging the liquid after absorption. In Patent Document 2, the moisture suction nozzle is pressed against the sponge portion of the draining roll to remove moisture from the sponge portion. However, since the draining roll always slides against the moisture suction nozzle, the sponge portion of the draining roll is It was easy to tear, and there was a problem that it could not withstand continuous use for several months.

  The present invention has been made in view of the above circumstances, has low noise, low energy waste, low possibility of recontamination, can be applied to a wide plate, and can withstand continuous use for a long time. It is an object of the present invention to provide a liquid removing device for a plate surface and a method for removing a liquid on a plate surface.

[1] A draining roll provided with a porous elastic body layer capable of absorbing liquid adhering to the plate surface on the roll surface, and a squeezing roll pressed against the draining roll so as to crush the porous elastic body layer And the liquid squeezed from the porous elastic layer by the squeezing roll is configured to be discharged along the rotation axis direction of the squeezing roll and the draining roll. A liquid removing device for a plate surface.
[2] The plate surface liquid removing apparatus according to [1], wherein a discharge groove is formed between the draining roll and the squeezing roll.
[3] The plate surface liquid removing apparatus according to [2], wherein a suction pipe for liquid suction is inserted into the discharge groove.
[4] The draining wiper blade is attached to the squeezing roll, and a discharge basket is attached to the draining wiper blade. A device for removing liquid from the plate surface.
[5] A draining roll provided with a porous elastic layer on the roll surface is brought into contact with the surface of the plate in the plate, and the liquid adhering to the surface of the plate is transferred to the porous elastic layer. While continuously absorbing, by pressing the squeezing roll against the draining roll and crushing the porous elastic layer, the liquid absorbed in the porous elastic layer is continuously squeezed out and squeezed out A method for removing a liquid on a plate surface, wherein the liquid is discharged along a rotation axis direction of the squeezing roll and the draining roll.
[6] The method for removing a liquid on the plate surface according to [5], wherein a draining groove is formed between the draining roll and the squeezing roll, and the liquid is discharged by the groove.

In the plate surface liquid removing apparatus of the present invention, the liquid on the plate surface is absorbed by the porous elastic layer of the draining roll, and the absorbed liquid is squeezed out by the squeezing roll pressed against the draining roll, and further squeezed out. The discharged liquid is discharged along the width direction of the squeeze roll and draining roll. Thereby, since no high-pressure gas is used when removing the liquid on the plate surface, noise is not generated and energy consumption can be reduced. In addition, since the squeezing roll does not slide with respect to the porous elastic body layer, there is no possibility that the porous elastic body layer is broken, and the squeezed liquid is continuously discharged along the rotation axis direction of the squeezing roll and the draining roll. Therefore, continuous operation over a long period of time becomes possible.
Further, according to the apparatus for removing liquid from the plate surface of the present invention, since the draining groove is formed between the draining roll and the squeezing roll, the squeezed liquid is stored in the groove and is transmitted along the groove. The liquid can be continuously discharged toward the rotation axis direction of the draining roll and the squeezing roll.
Furthermore, according to the apparatus for removing a liquid from the plate surface according to the present invention, since the suction pipe for sucking the liquid is inserted into the groove, the squeezed liquid can be quickly discharged.
Furthermore, according to the apparatus for removing liquid from the plate surface according to the present invention, the wiper blade for draining is attached to the squeezing roll, and the drainage ridge is attached to the wiper blade for draining. It can be removed, and there is no possibility that the liquid will re-adhere from the squeeze roll to the porous elastic layer.

Further, according to the method for removing the liquid on the plate surface of the present invention, the liquid on the plate surface is absorbed by the porous elastic body layer of the draining roll, and the absorbed liquid is squeezed out by the squeezing roll pressed against the draining roll, Furthermore, since the squeezed liquid is discharged along the rotation axis direction of the squeeze roll and draining roll, no high pressure gas is used to remove the liquid on the plate surface, no noise is generated, and energy consumption is reduced. The amount is also reduced. Further, since the squeezing roll does not slide with respect to the porous elastic body layer, there is no possibility that the porous elastic body layer is broken, and the squeezed liquid is continuously discharged along the rotation axis direction of the squeezing roll and the draining roll. Therefore, it can operate continuously for a long time.
Furthermore, according to the method for removing liquid from the plate surface according to the present invention, the draining groove is formed between the draining roll and the squeezing roll, so that the squeezed liquid is stored in the groove and transmitted through the groove. Thus, the liquid can be continuously discharged toward the rotation axis direction of the draining roll and the squeezing roll.

FIG. 1 is a schematic side view illustrating a plate surface liquid removing apparatus according to an embodiment of the present invention. FIG. 2 is a schematic plan view showing a plate surface liquid removing apparatus according to an embodiment of the present invention. FIG. 3 is a schematic side view showing another example of the plate surface liquid removing apparatus according to the embodiment of the present invention. FIG. 4 is a schematic side view showing another example of the plate surface liquid removing apparatus according to the embodiment of the present invention. FIG. 5 is a schematic side view showing another example of the plate surface liquid removing apparatus according to the embodiment of the present invention.

Embodiments of the present invention will be described below with reference to the drawings.
The plate surface removal apparatus 1 of this embodiment is used, for example, when removing liquid adhering to the surface of various metal plates such as steel plates or resin plates. More specifically, for example, installed in an ultrasonic flaw detection inspection process for steel sheets, a pickling process for steel sheets, a plating process for steel sheets, etc., an acidic solution such as water, dilute hydrochloric acid, dilute sulfuric acid, an alkaline solution such as caustic soda, It is used when removing a liquid after depositing a liquid such as a plating bath. In the following description, the case where the liquid on the steel sheet surface is removed will be described.

  The plate surface liquid removing device 1 shown in FIG. 1 is pressed against a draining roll 3 having a porous elastic layer 2 provided on a roll surface 3a, and the draining roll 3 so as to crush the porous elastic layer 2. The squeezing roll 4 is provided. Further, in the liquid removing apparatus 1 of the present embodiment, a draining roll reduction cylinder 5 for pressing the draining roll 3 against the surface 11 a of the steel plate 11, and a drawing roll reduction cylinder for pressing the drawing roll 4 against the draining roll 3. 6 are provided. In the example shown in FIG.1 and FIG.2, the conveyance path H of the steel plate 11 is installed under the draining roll 3. FIG.

  The draining roll 3 includes a roll body 3b and a porous elastic body layer 2 provided over the entire width of the peripheral surface of the roll body 3b. The surface of the porous elastic layer 2 is a roll surface 3 a of the draining roll 3. The peripheral surface of the roll body 3b is made of a hard material such as metal or ceramics. The draining roll 3 is configured to rotate in accordance with the movement of the steel plate 11. The draining roll 3 may be rotated by a rotary drive device or the like, or may be rotated by a steel plate 11 to be passed.

  The porous elastic body layer 2 can be exemplified by a porous elastic body such as sponge, non-woven fabric, and sponge. Since the porous elastic body layer 2 is in contact with the steel plate surface, the liquid adhering to the surface 11a of the steel plate 11 can be absorbed by a capillary phenomenon. Further, as will be described later, the absorbed liquid can be squeezed out by crushing the porous elastic layer 2 with the squeezing roll 4. Further, the thickness t of the porous elastic layer 2 may be determined in consideration of the amount of liquid adhering to the surface 11a of the steel plate 11, the liquid absorption amount per volume of the porous elastic layer 2, and the like.

In addition, as shown in FIG. 2, the roll width w ₁ of the draining roll 3 needs to be larger than the plate width w of the steel plate 11. In order to remove the liquid adhering to the surface 11 a of the steel plate 11, it is sufficient to make the roll width w _{1 the} same as the plate width w of the steel plate 11, but in the removing device 1 of the present embodiment, the squeezing roll 4 squeezed out. Since the liquid is discharged from both ends of the draining roll in the width direction, the edge of the steel plate becomes dirty unless the roll length is longer than the plate width (also to prevent the discharged liquid from reattaching to the steel plate 11). The width w ₁ is made larger than the plate width w of the steel plate 11.

  The draining roll reduction cylinder 5 presses the draining roll 3 against the surface 11a of the steel plate 11 with an appropriate pressure. If the pressure applied by the draining roll reducing cylinder 5 is too high, the porous elastic body layer 2 is crushed on the surface 11a of the steel plate 11, and the liquid adhering to the surface 11a cannot be sufficiently absorbed. Since the liquid remaining in the layer 2 is squeezed out, the amount of reduction should be adjusted in accordance with the hardness of the porous elastic body layer 2.

  Next, the squeeze roll 4 shown in FIGS. 1 and 2 is disposed adjacent to the draining roll 3. The rotary shaft 4 a of the squeezing roll 4 is positioned so as to be substantially parallel to the rotary shaft 3 c of the draining roll 3. Thereby, the roll surface 4b of the squeezing roll 4 is brought into contact with the porous elastic body layer 2 of the draining roll 3 over its entire width. The squeezing roll 4 is preferably rotated with the rotation of the draining roll 3. The peripheral speeds of the roll surfaces of the rolls 3 and 4 are preferably matched. If the peripheral speeds of the roll surfaces of the rolls 3 and 4 are different, there is a possibility that the porous elastic body layer 2 is damaged due to a shearing force applied thereto, which is not preferable. The squeeze roll 4 may be rotated by a rotation driving device or may be rotated by the draining roll 3.

In FIG. 1, the height h ₂ from the steel plate surface 11 a of the rotary shaft 4 a of the squeezing roll 4 is set to be substantially the same as the height h ₁ from the steel plate surface of the rotary shaft 3 c of the draining roll 3. Has been. Thereby, a recess capable of holding the liquid is formed between the squeezing roll 4 and the draining roll 3. This recess becomes a groove 7 for discharging liquid. The liquid discharge groove 7 extends in the direction of the rotation axis of the draining roll 3 and the squeezing roll 4. The height h ₂ of the rotation shaft 4a of the squeeze roll 4 is necessarily need not be exactly the same as the height h ₁ from the steel sheet surface of the rotary shaft 3c of the draining roll 3, the rotary shaft 4a High When the h ₂ is too low, squeeze rolls 4 is not preferable because thereby contacts the steel plate 11, the height h ₂ of the rotational shaft 4a is too high, while a depression capable of holding liquid of each roll 3 and 4 Cannot be formed. Therefore, the height h ₂ may be adjusted within a range in which the squeeze roll 4 does not contact the steel plate 11 and a recess (groove 7) capable of holding liquid can be formed.

  Further, as shown in FIGS. 1 and 2, the squeezing roll 4 is rotated 180 in the rotational direction of the draining roll 3 from the position where the draining roll 3 and the steel plate 11 are in contact with each other about the rotating shaft 3 c of the draining roll 3. It is preferably in contact with the draining roll 3 at a position rotated by more than °. In other words, it is preferable that the squeezing roll 4 is disposed on the side where the roll surface 3a of the draining roll 3 moves downward when the rotating shaft 3c of the draining roll 3 is oriented in the horizontal direction. If the squeezing roll 4 is in contact with the draining roll 3 on the side where the roll surface 3a of the draining roll 3 moves upward, the liquid squeezed out by the squeezing roll 4 falls on the steel plate 11, which is not preferable. .

  The squeezing roll 4 preferably has a roll surface 4b made of a hard material, and may be made of metal, ceramics, hard rubber, or the like. Since the roll surface 4b is made of a hard material, the porous elastic body layer 2 is sandwiched between the squeezing roll 4 and the roll body 3a of the draining roll 3 and the liquid can be squeezed out.

  The diameter of the squeeze roll 4 is preferably about 30 to 80% of the diameter of the draining roll 3. If the diameter of the squeezing roll 4 is less than 30% of the diameter of the draining roll 3, the recess (groove 7) that can hold the liquid becomes too small, and the squeezed liquid may overflow, and the squeezing roll 4 bends. This is not preferable because of fear. Further, when the diameter of the squeezing roll 4 exceeds 80% of the diameter of the draining roll 3, the linear pressure of the squeezing roll 4 with respect to the draining roll 3 decreases, and the liquid absorbed by the porous elastic body layer 2 can be sufficiently squeezed out. Since it disappears, it is not preferable.

Furthermore, the width w ₂ of the squeezing roll 4 is preferably the same as the width w _{1 of the} draining roll. If there is a difference between the widths w ₁ and w ₂ of the rolls 3 and 4, the liquid discharged from both ends of the rolls 3 and 4 is transmitted to the wide rolls, which makes it impossible to smoothly drain the liquid. Absent. Further, if the width w ₂ of the squeezing roll 4 is smaller than the width w _{1 of the} draining roll, it is not preferable because the liquid cannot be squeezed over the entire width of the porous elastic body layer 2.

  The squeezing roll reducing cylinder 6 presses the squeezing roll 4 against the draining roll 3 with an appropriate pressure. The optimum pressure is preferably adjusted so that the thickness of the porous elastic body layer 2 when crushed is about 30 to 80% of the original thickness t of the porous elastic body layer 2. When the pressure applied to the squeezing roll 4 by the squeezing roll reducing cylinder 6 is too low and the thickness of the porous elastic layer 2 exceeds 80% of the original thickness t, the liquid absorbed by the porous elastic layer 2 is reduced. It is not preferable because it cannot be squeezed out sufficiently. Further, if the pressure applied by the squeezing roll reduction cylinder 6 is too high and the thickness of the porous elastic layer 2 is less than 30% of the original thickness t, the porous elastic layer 2 may be damaged, which is preferable. Absent.

  Next, a method for removing the liquid on the steel sheet surface using the removing apparatus 1 shown in FIGS. 1 and 2 will be described. The steel plate 11 applied to the removal method of the present embodiment may be any of a thick plate, a thin plate, and a plated steel plate. The liquid adhering to the surface 11a of the steel plate 11 may be any of water, an acidic solution such as dilute hydrochloric acid and dilute sulfuric acid, an alkaline solution such as caustic soda, a plating bath solution, and fats and oils such as lubricating oil. These liquids adhere to the steel sheet in the ultrasonic flaw detection inspection process of the steel sheet, the pickling process of the steel sheet, the plating process of the steel sheet, and the like.

  First, as shown in FIGS. 1 and 2, the steel plate 11 with various liquids 12 attached to the surface 11 a is continuously passed through the removing device 1 in the direction of the arrow A. And the draining roll 3 is made to contact the surface 11a of the steel plate 11, and the liquid 12 adhering to the surface 11a of the steel plate 11 is made to absorb into the porous elastic body layer 2. FIG. The porous elastic layer 2 continuously absorbs the liquid 12 while the draining roll 3 rotates in accordance with the plate passing speed of the steel plate 11.

  Next, the porous elastic body layer 2 that has absorbed the liquid 12 is sent to the contact position with the squeeze roll 4 as the draining roll 3 rotates. Then, the porous elastic body layer 2 is crushed and compressed by the squeezing roll 4, and the absorbed liquid is squeezed out. The squeezed liquid 12 loses its destination and is stored in a recess (groove 7) between the rolls 3 and 4. Then, as the steel plate 11 is continuously passed, the amount of the liquid 12 accumulated in the groove 7 increases, and is finally discharged from both ends of the rolls 3 and 4 in the width direction.

  The porous elastic body layer 2 after the liquid 12 is squeezed out by the squeezing roll 4 returns to a state in which the liquid can be absorbed. Then, due to the rotation of the draining roll 3, the liquid 12 is absorbed by coming into contact with the surface 11a of the steel plate 11 again.

As described above, in the removal apparatus 1 and the removal method of the present embodiment, the liquid 12 on the surface 11 a of the steel plate 11 is absorbed by the porous elastic body layer 2 of the draining roll 3 and pressed against the draining roll 3. The absorbed liquid 12 is squeezed out by the squeezing roll 4, and further, the squeezed liquid 12 is discharged in the direction along the rotation axis of the squeezing roll 4 and the draining roll 3. Thereby, when removing the liquid 12 on the surface 11a of the steel plate 11, high pressure gas is not used, noise is not generated, and energy consumption can be reduced. Further, since the squeezing roll 4 does not slide with respect to the porous elastic body layer 2, there is no possibility that the porous elastic body layer 2 is torn. Since it is continuously discharged along, continuous operation over a long period of time becomes possible.
Moreover, since the groove | channel 7 for discharge | emission is comprised by the hollow between the draining roll 3 and the squeezing roll 4, the squeezed liquid 12 is stored in the groove | channel 7, and the liquid 12 is made to drain through the groove | channel 7 and drains. 3 and the squeezing roll 7 can be continuously discharged in the direction of the rotation axis, and reattachment to the steel plate 11 can be prevented.

Further, since the roll widths w ₁ and w _{2 of} the draining roll 3 and the squeezing roll 4 are larger than the plate width w of the steel plate 11, the liquid discharged from both ends in the width direction of the rolls 3 and 4 is reattached to the steel plate 11. There is no possibility of contaminating the steel plate 11.

  Further, when the rotary shaft 3c of the draining roll 3 is directed in the horizontal direction, the squeezing roll 4 is disposed on the side where the roll surface 3a of the draining roll 3 moves downward. The liquid thus collected can be stored in the groove 7, and the squeezed liquid does not fall on the steel plate 11 as it is.

Furthermore, since the width w ₂ of the squeeze roll 4 and the width w _{1 of the} draining roll are the same, the liquid can be smoothly discharged from both ends in the width direction of the rolls 3 and 4.

  Further, even when the steel plate 11 in the through plate is bent and the surface 11a does not become a flat surface, the porous elastic body layer 2 provided on the roll surface of the draining roll 3 follows the bent surface 11a. Therefore, the liquid can be absorbed from both surfaces 11a of the steel plate 11.

Next, another example of the removing device will be described with reference to the drawings. In FIG. 3, the removal apparatus 21 which is another example of this embodiment is shown.
In the removing device 21 shown in FIG. 3, a liquid suction pipe 22 is inserted into the groove 7 between the draining roll 3 and the squeezing roll 4. The suction pipe 22 is connected to a suction pump (not shown) so that the liquid accumulated in the groove 7 can be sucked.

  3 removes the liquid 12 on the surface 11a of the steel plate 11 in the porous elastic body layer 2 of the draining roll 3 and causes the draining roll 3 to The absorbed liquid 12 is squeezed out by the pressed squeezing roll 4, and further, the squeezed liquid 12 is discharged along the rotation axis direction of the squeezing roll 4 and the draining roll 3. At this time, when a large amount of liquid accumulates in the groove 7 and the discharge from the both ends in the width direction of the rolls 3 and 4 is not in time, the liquid can be efficiently discharged by sucking the liquid with the suction pipe 22. Can do.

Next, another example of the removing device will be described with reference to the drawings. In FIG. 4, the removal apparatus 31 which is another example of this embodiment is shown.
In the removing device 31 shown in FIG. 4, a draining wiper blade 32 is attached to the squeezing roll 4 over the entire width of the squeezing roll 4, and a drainage ridge 33 is attached to the draining wiper blade 32. ing.

  4 removes the liquid 12 on the surface 11a of the steel plate 11 into the porous elastic body layer 2 of the draining roll 3 and causes the draining roll 3 to The absorbed liquid 12 is squeezed out by the pressed squeezing roll 4, and further, the squeezed liquid 12 is discharged along the rotation axis direction of the squeezing roll 4 and the draining roll 3. At this time, the liquid adhering to the roll surface 4 a of the squeezing roll 4 is wiped by the draining wiper blade 32, and the wiped liquid is further discharged to the drainage basin 33. Thus, by removing the liquid adhering to the squeezing roll 4, the liquid can be efficiently discharged from the removing device 31. Further, there is no possibility that the liquid is reattached from the squeezing roll 4 to the porous elastic body layer 2.

  Moreover, you may attach the suction pipe 22 of the removal apparatus 21 shown in FIG. 3 to the removal apparatus 31 shown in FIG.

Next, another example of the removal device will be described with reference to the drawings. In FIG. 5, the removal apparatus 41 which is the other example of this embodiment is shown.
The removing device 41 shown in FIG. 5 includes a removing device 1a that removes the liquid on the surface 11a of the steel plate 11, and a removing device 1b that removes the liquid on the surface 11b opposite to the surface of the steel plate 11. Each removing device 1a, 1b is provided with a turn roll 42, 42 that is paired with each draining roll 3, 3.

  5 removes the liquid adhering to both surfaces 11a and 11b by bringing the draining rolls 3 and 3 into contact with both surfaces 11a and 11b of the steel plate bent into a cylindrical surface by each turn roll 42. . In this removing device 41, even if both surfaces 11a and 11b of the steel plate are deformed into a cylindrical shape, the porous elastic body layer 2 provided on the roll surface of the draining roll 3 has both surfaces 11a of the steel plate deformed into a cylindrical shape. , 11b, and the liquid can be absorbed from both surfaces 11a, 11b of the steel plate 11.

  In the present embodiment, the removal apparatus 1 has been described by taking a steel plate as an example, but the present invention is not limited to a steel plate, and can be applied to a metal plate other than a steel plate, a resin plate, or the like.

  1, 2, 31, 41 ... removal device (liquid removal device on the steel sheet surface), 2 ... porous elastic layer, 3 ... draining roll, 3a ... roll surface, 4 ... squeezing roll, 7 ... draining groove, 11 DESCRIPTION OF SYMBOLS ... Steel plate, 11a ... Steel plate surface (steel plate surface), 12 ... Liquid, 22 ... Suction pipe for liquid suction, 31 ... Wiper blade for draining water, 32 ... Spear for discharge.

Claims (6)

A draining roll provided with a porous elastic layer on the roll surface capable of absorbing the liquid adhering to the plate surface;
A squeezing roll pressed against the draining roll so as to crush the porous elastic layer,
The liquid on the plate surface is configured such that the liquid squeezed from the porous elastic body layer by the squeezing roll is discharged along the rotation axis direction of the squeezing roll and the draining roll. Removal device.   The plate surface liquid removing apparatus according to claim 1, wherein a discharge groove is formed between the draining roll and the squeezing roll.   The liquid removal apparatus for a plate surface according to claim 2, wherein a suction pipe for liquid suction is inserted into the groove for discharge.   4. The plate surface according to claim 1, wherein a draining wiper blade is attached to the squeezing roll, and a draining ridge is attached to the draining wiper blade. 5. Liquid removal device.   A draining roll provided with a porous elastic layer on the roll surface is brought into contact with the surface of the plate in the plate, and the liquid adhering to the surface of the plate is continuously applied to the porous elastic layer. And absorbing the squeezing roll against the draining roll to crush the porous elastic layer, thereby continuously squeezing out the liquid absorbed in the porous elastic layer and the squeezed liquid A method for removing a liquid on the surface of a steel sheet, wherein the liquid is discharged along a rotation axis direction of the squeeze roll and the draining roll.   6. The method for removing a liquid on the surface of a steel sheet according to claim 5, wherein a draining groove is formed between the draining roll and the squeezing roll, and the liquid is discharged by the groove.

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